Adding
Natural Uncertainty Improves Mathematical Models
PROVIDENCE , R.I. [Brown University ]
September 29, 2014 —
Mathematicians from Brown
University
Solving these equations is computationally expensive, and only in recent years has computing power reached a level that makes such calculations possible.
Ironically, allowing uncertainty into a
mathematical equation that models fluid flows makes the equation much more
capable of correctly reflecting the natural world — like the formation,
strength, and position of air masses and fronts in the atmosphere.
The research, published
in Proceedings of the Royal Society A,
deals with Burgers’ equation, which is used to describe turbulence and shocks
in fluid flows. The equation can be used, for example, to model the formation
of a front when airflows run into each other in the atmosphere.
“Say you have a wave
that’s moving very fast in the atmosphere,” said George Karniadakis, the
Charles Pitts Robinson and John Palmer Barstow Professor of Applied Mathematics
at Brown and senior author of the new research. “If the rest of the air in the
domain is at rest, then flow one goes over the other. That creates a very stiff
front or a shock, and that’s what Burgers’ equation describes.”
It does so, however, in
what Karniadakis describes as “a very sterilized” way, meaning the flows are
modeled in the absence of external influences.
For example, when
modeling turbulence in the atmosphere, the equations don’t take into
consideration the fact that the airflows are interacting not just with each
other, but also with whatever terrain may be below — be it a mountain, a valley
or a plain. In a general model designed to capture any random point of the
atmosphere, it’s impossible to know what landforms might lie underneath. But
the effects of whatever those landforms might be can still be accounted for in
the equation by adding a new term — one that treats those effects as a “random
forcing.”
In this latest research,
Karniadakis and his colleagues showed that Burgers’ equation can indeed be
solved in the presence of this additional random term. The new term produces a
range of solutions that accounts for uncertain external conditions that could
be acting on the model system.
The work is part of a
larger effort and a burgeoning field in mathematics called uncertainty
quantification (UQ). Karniadakis is leading a Multidisciplinary University
Research Initiative centered at Brown to lay out the mathematical foundations
of UQ.
“The general idea in UQ,”
Karniadakis said, “is that when we model a system, we have to simplify it. When
we simplify it, we throw out important degrees of freedom. So in UQ, we account
for the fact that we committed a crime with our simplification and we try to
reintroduce some of those degrees of freedom as a random forcing. It allows us
to get more realism from our simulations and our predictions.”
Solving these equations is computationally expensive, and only in recent years has computing power reached a level that makes such calculations possible.
“This is something people
have thought about for years,” Karniadakis said. “During my career, computing
power has increased by a factor of a billion, so now we can think about
harnessing that power.”
The aim, ultimately, is
to make the mathematical models describing all kinds of phenomena — from
atmospheric currents to the cardiovascular system to gene expression — that
better reflect the uncertainties of the natural world.
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